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CN113241196B - Remote medical treatment and grading monitoring system based on cloud-terminal cooperation - Google Patents

Remote medical treatment and grading monitoring system based on cloud-terminal cooperation Download PDF

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CN113241196B
CN113241196B CN202110536468.2A CN202110536468A CN113241196B CN 113241196 B CN113241196 B CN 113241196B CN 202110536468 A CN202110536468 A CN 202110536468A CN 113241196 B CN113241196 B CN 113241196B
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王晓
王飞跃
朴然
国元元
王静
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Qingdao Academy Of Intelligent Industries
Institute of Automation of Chinese Academy of Science
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Institute of Automation of Chinese Academy of Science
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Abstract

The invention belongs to the technical field, and particularly relates to a cloud-terminal cooperation-based remote medical and grading monitoring system, which comprises a data acquisition module, an interactive terminal module and a cloud data integration module, wherein the data acquisition module is used for acquiring medical data of a patient; the data acquisition module is used for acquiring patient data; the interactive terminal module is used for single sign-on of the patient, data input and diagnosis information output; the cloud data integration module comprises a data receiving module, an information processing module and an information output module, and the information processing module is used for processing case information and outputting a final disease treatment scheme; the information output module is used for transmitting information; the invention can ensure that the patient can obtain better medical effect without going out of home, customize a private doctor for the patient, ensure that the treatment scheme is relatively accurate and reliable, simultaneously relieve the pressure of the doctor for the hospital and improve the working efficiency.

Description

Remote medical treatment and grading monitoring system based on cloud-terminal cooperation
Technical Field
The invention belongs to the technical field of medical information, and particularly relates to a remote medical and grading monitoring system based on cloud-terminal cooperation.
Background
In the prior art, patients with various diseases are growing day by day, but at present, medical resources are limited, medical institutions in different areas have uneven medical resource distribution, part of the medical institutions are full of patients every day, and some of the medical institutions are in loss operation every day, the foundation is that the medical levels mainly have differences, and after a disease is suffered, people often select a hospital for treatment according to the strength of the medical institutions, so that the difference among different medical institutions in the same area is further enlarged, the waste of the medical resources is caused, the treatment efficiency of the patients is greatly reduced, and the treatment service quality of the patients is reduced; medical institutions face the problem of data sharing all the time, mainly because different medical institutions and different information systems form data islands, and uniform views centering on residents are difficult to realize; compared with the growing patients with various diseases, the diagnosis and treatment problems that the medical resources are limited, the medical resources in the region are unbalanced, the technical levels of medical staff are uneven, the patient has long time to look at a doctor and delay treatment and the like are increasingly prominent.
Disclosure of Invention
In order to solve the problems, namely to improve medical efficiency, realize accurate treatment and remote treatment, the invention provides a remote medical treatment and grading monitoring system based on cloud-terminal cooperation, which comprises a data acquisition module, an interactive terminal module and a cloud data integration module, wherein the data acquisition module and the interactive terminal module are in communication connection with the cloud data integration module;
the data acquisition module is used for acquiring medical data of a patient; the data acquisition module comprises an intelligent wearable device data acquisition module and an intelligent detection device data acquisition module, and is respectively used for data acquisition of the patient long-term wearable device and the patient temporary detection device;
the interactive terminal module is used for single sign-on of a patient, data input and diagnosis information output;
the cloud data integration module comprises a data receiving module, an information processing module and an information output module, and the data receiving module and the information output module are in communication connection with the information processing module; the data receiving module is used for receiving the data output by the data acquisition module; the information processing module comprises a database and a machine self-learning module, and the database is used for storing various case information and case auxiliary strategies; the machine self-learning module processes based on actual case information and stored case information, automatically generates a treatment scheme, compares the automatically generated treatment scheme with an expert data customization scheme input from the outside and outputs a final disease treatment scheme; the information output module transmits to the interactive terminal module based on the received final disease treatment plan.
In some preferred embodiments, the treatment regimen comprises a first treatment regimen, a second treatment regimen, and a third treatment regimen;
the first treatment scheme is a first-level treatment scheme, and specifically comprises the steps of abstracting received case data into symptoms, searching similar cases based on the symptom characteristics and cosine similarity stored in the database, obtaining three similar cases in sequence, and formulating a diet work and rest suggestion scheme based on the three cases; wherein symptoms are stored in vector form;
the second treatment scheme is a secondary treatment scheme, and specifically comprises the steps of outputting a change scheme of the medicament quantity based on the received case information by utilizing a universal approximation theorem of a T-S type fuzzy neural network, wherein the change scheme comprises increasing a preset dose, keeping the dose unchanged and reducing the preset dose;
the third treatment plan is a three-level treatment plan, and specifically comprises a multi-party remote consultation based on abnormal case data information to make a final treatment plan.
In some preferred embodiments, the T-S type fuzzy neural network includes a front part network and a back part network, the front part network includes a membership function layer, a rule layer, and a normalization layer, the membership function layer is obtained by selecting a gaussian function, and the membership function specifically is:
Figure BDA0003070032170000031
Figure BDA0003070032170000032
n ═ 1, 2.. n; j ═ 1, 2.. m; the rule layer is responsible for fuzzy rule output, and fuzzy calculation is carried out on fuzzy subsets of each feature output by the membership function; adopting the form of arithmetic product as the operation method of the fuzzy rule layer, and recording the output of the rule layer as:
Figure BDA0003070032170000033
j is 1, 2,. said, m; the normalization layer rule layer outputs are normalized, and specifically:
Figure BDA0003070032170000034
Figure BDA0003070032170000035
j=1,2,...,m;
the back-part neural network comprises a T-S type fuzzy logic layer and an output layer, wherein the output of the T-S type fuzzy logic layer is combined with the linear sum of the normalization layer output and the input layer, and the output theta is thetajComprises the following steps:
Figure BDA0003070032170000036
1, 2,. m; j is 1, 2,. said, m; the output layer is an output layer with an activation function structure and has the range of [ -1,1 [ -1 [ ]]。
In some preferred embodiments, the primary treatment plan specifically includes an algorithm of: storing symptom information in a database in the form of vectors, wherein each piece of information comprises a symptom number and a corresponding symptom vector;
recording a treatment set obtained based on prior knowledge as D, and removing symptom vectors corresponding to all symptom numbers with treatment D;
representing the input symptoms by vectors, and calculating the similarity of the input symptoms and every other symptom vector by using cosine similarity;
sorting the symptoms according to the similarity, and taking out the first 3 symptoms to be stored in an array;
and displaying the whole information with the closer first 3 similarity degrees, including the number corresponding to the input symptom, the similarity degree, the symptom, the treatment and the medication information.
In some preferred embodiments, the fuzzy classification included in the treatment protocol specifically comprises the steps of:
dividing the factor set into N factor subsets according to the dividing factor set U and the comment set V;
performing primary fuzzy comprehensive judgment on U, and setting the fuzzy subset of the importance degree of U as A and UiK ofiThe comprehensive evaluation matrix of the factor to V is RiAnd the comprehensive evaluation set is Bi=Ai*Ri
Performing two-stage fuzzy comprehensive evaluation on U, and setting the factor importance degree fuzzy subset of U as A and the two-stage comprehensive evaluation matrix as
Figure BDA0003070032170000041
And (5) carrying out diagnosis and treatment grade evaluation according to the maximum membership principle.
In some preferred embodiments, the information collected by the data collection module is one or more of medical record information, assay result information, daily monitoring result information, and imaging report information.
In some preferred embodiments, the information processing module further comprises an information updating module configured to perform integration and update of the same patient case information based on the input case information and pre-stored case information.
In some preferred embodiments, the interactive terminal module includes a mobile terminal, and the mobile terminal is a mobile phone, a computer, a tablet or a bracelet.
In some preferred embodiments, the smart wearable device data acquisition module comprises a bracelet;
the intelligent detection equipment data acquisition module comprises a blood pressure meter, a blood glucose meter or a uric acid meter.
In some preferred embodiments, the communication in the system employs a 5G network.
1) The invention provides a cloud-end cooperative remote medical treatment and hierarchical monitoring system, which achieves the purposes of utilizing a large number of patient data training models, maximally utilizing case data and diagnosis and treatment results, accurately and efficiently diagnosing and treating patients, relieving the pressure of hospital treatment and providing a reliable medical platform between the patients and the hospital.
2) According to the invention, the human health data are acquired by various health information acquisition devices and are remotely transmitted to the cloud, and different processing measures are selected according to corresponding levels by utilizing a graded treatment scheme through cloud big data decision, and the scheme is implemented locally. The medical and monitoring platform includes: A. the collecting terminal comprises an intelligent wearable device sign collecting module, an intelligent patient user interaction interface module and a community medical data collecting module; B. the cloud server end comprises an intelligent detection module, a medical grading module, an intelligent decision-making model module and a grading medical scheme module; C. the cloud hierarchical monitoring is divided into three levels, and treatment schemes at all levels relate to different points. The first grade is through proposing the adjustment patient diet motion and the life work and rest to guide patient's treatment process, and the second grade is calculated through the high in the clouds, carries out patient's medicine dose adjustment, and the health data through gathering, adjustment treatment scheme is directly docked to the tertiary real doctor. The cloud-end cooperative remote medical treatment and grading monitoring platform adopted by the invention can ensure that a patient can not go out of home sufficiently, a better medical treatment effect can be obtained, a private doctor is customized for the patient, the treatment scheme is relatively accurate and reliable, safe and effective medical observation and treatment are ensured, the pressure of visiting a doctor is relieved for hospital departments, the working efficiency is improved, the disease treatment of a large number of patients is better helped, and a reliable and effective solution is provided for intelligent medical treatment.
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Other features, objects and advantages of the present application will become more apparent upon reading of the following detailed description of non-limiting embodiments thereof, made with reference to the accompanying drawings in which:
FIG. 1 is a schematic diagram of a frame structure of an embodiment of the present invention;
FIG. 2 is a schematic diagram of a framework for one embodiment of the therapeutic staging of the present invention;
FIG. 3 is a schematic flow diagram of a primary treatment protocol in the present invention;
FIG. 4 is a schematic representation of a membership function in the present invention;
fig. 5 is a schematic diagram of an optimal solution acquisition process of the fuzzy neural network in the secondary treatment scheme of the present invention.
Detailed Description
In order to make the embodiments, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is apparent that the described embodiments are some, but not all embodiments of the present invention. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention.
The invention provides a remote medical treatment and grading monitoring system based on cloud-terminal cooperation, which comprises a data acquisition module, an interactive terminal module and a cloud data integration module, wherein the data acquisition module and the interactive terminal module are in communication connection with the cloud data integration module; the data acquisition module is used for acquiring medical data of a patient; the data acquisition module comprises an intelligent wearable device data acquisition module and an intelligent detection device data acquisition module, and is respectively used for data acquisition of the patient long-term wearable device and the patient temporary detection device; the interactive terminal module is used for single sign-on of the patient, data input and treatment information output; the cloud data integration module comprises a data receiving module, an information processing module and an information output module, and the data receiving module and the information output module are in communication connection with the information processing module; the data receiving module is used for receiving the data output by the data acquisition module; the information processing module comprises a database and a machine self-learning module, and the database is used for storing various case information and case auxiliary strategies; the machine self-learning module processes based on the actual case information and the stored case information, automatically generates a treatment scheme, compares the automatically generated treatment scheme with an expert data customization scheme input from the outside and outputs a final disease treatment scheme; the information output module transmits the final disease treatment scheme to the interactive terminal module based on the received final disease treatment scheme.
The invention is further described with reference to the following detailed description of embodiments with reference to the accompanying drawings.
Referring to fig. 1, fig. 1 is a schematic diagram of a framework structure of an embodiment of the present invention, and provides a remote medical treatment and hierarchical monitoring system based on cloud-terminal cooperation, in which human health data are acquired by various health information acquisition devices, remotely transmitted to a cloud, and subjected to a hierarchical treatment scheme, different treatment measures are selected according to corresponding levels, and the scheme is implemented locally; the system comprises a data acquisition module, an interactive terminal module and a cloud data integration module, wherein the data acquisition module and the interactive terminal module are in communication connection with the cloud data integration module; the data acquisition module is used for acquiring medical data of a patient, and comprises an intelligent wearable device data acquisition module and an intelligent detection device data acquisition module so as to be respectively used for acquiring data of long-term wearable devices of the patient and temporary detection devices of the patient. The interactive terminal module is used for single sign-on of the patient, data input and treatment information output, and privacy of the patient is guaranteed through single sign-on setting. The cloud data integration module comprises a data receiving module, an information processing module and an information output module, and the data receiving module and the information output module are in communication connection with the information processing module. The data receiving module is used for receiving the data output by the data acquisition module. The information processing module comprises a database and a machine self-learning module, and the database is used for storing various case information and case auxiliary strategies; the machine self-learning module processes based on the actual case information and the stored case information, automatically generates a treatment scheme, compares the automatically generated treatment scheme with an expert data customization scheme input from the outside and outputs a final disease treatment scheme; the information output module transmits the final disease treatment scheme to the interactive terminal module based on the received final disease treatment scheme.
The acquisition equipment related to the data acquisition module is simple and easy to use, various sensors and portable mobile equipment on the body form a network in a distributed mode, personal data change tracks are recorded, data can be timely and accurately uploaded to the cloud, and the efficiency of monitoring the medical effect of a patient is improved; the data acquisition module can also acquire community medical data, and local centralized sampling and information data uploading are performed through areas such as community hospitals, so that the defects of intelligent equipment are overcome; by the system provided by the invention, the data of the patient can be acquired not only by wearing the patient, but also form an internet with a remote server through each terminal device, so that the system covers densely populated places and has the characteristics of distribution and high concurrency.
The interactive terminal module submits reports including personal information to the cloud and feeds back treatment scheme adjustment measures and expert suggestions to the cloud, displays recent data reports, graphically displays prediction trends, enables patients to know self medical effects and health conditions in real time, conveniently and efficiently treats the patients, and meanwhile relieves the pressure and burden of hospital visits. Products corresponding to the APP on the middle platform are intelligently and manually collected, and comprise an Android end, an iOS end and a WeChat applet end; after logging on, the health data of the individual can be viewed. The core function is as follows: the method comprises the steps of personnel identity identification, single sign-on, manual sign data entry, periodic automatic data uploading, historical data storage and the like.
The information processing module can combine a diagnosis model of medical knowledge with a machine learning and fuzzy mathematical diagnosis model based on clinical data to give an intelligent diagnosis result, give a diagnosis basis and a process explanation, grade a treatment scheme of a patient, and input a corresponding grading diagnosis and treatment model according to different grades.
Specifically, the treatment scheme is a hierarchical medical scheme and mainly comprises three levels, wherein the emphasis points of each level of treatment scheme are different, the first level guides the treatment process of a patient by suggesting and adjusting the diet exercise and the daily work and rest of the patient, the second level adjusts the drug dosage of the patient through cloud computing, the third level is directly connected with a real doctor, and the doctor adjusts the treatment scheme by feeding back acquired health data. The cloud-end cooperative remote medical treatment and grading monitoring system adopted by the invention can ensure that a patient can not go out of home sufficiently, a better medical treatment effect can be obtained, a private doctor is customized for the patient, the treatment scheme is relatively accurate and reliable, safe and effective medical observation and treatment are ensured, the pressure of visiting a doctor is relieved for hospital departments, the working efficiency is improved, the disease treatment of a large number of patients is better helped, and a reliable and effective solution is provided for intelligent medical treatment.
Further, the treatment scheme comprises a first treatment scheme, a second treatment scheme and a third treatment scheme, wherein the first treatment scheme is a first-level treatment scheme, and specifically comprises the steps of abstracting received case data into symptoms, searching similar cases based on the symptom characteristics and cosine similarity stored in the database, obtaining three similar cases in the top sequence, and making a diet work and rest suggestion scheme based on the three cases; wherein symptoms are stored in vector form; the second treatment scheme is a secondary treatment scheme, and specifically comprises the steps of outputting a change scheme of the medicament quantity based on the received case information by utilizing a universal approximation theorem of a T-S type fuzzy neural network, wherein the change scheme comprises increasing the preset dosage, keeping the dosage unchanged and reducing the preset dosage; the third treatment plan is a three-level treatment plan, and particularly comprises a multi-party remote consultation based on abnormal case data information to make a final treatment plan.
In this embodiment, the acquired treatment plan is three diagnosis models, which are a primary diagnosis model, a secondary diagnosis model and a tertiary diagnosis model, and based on the acquired patient case information, the corresponding diagnosis model is established, so that medical classification is realized in the processing process, and the optimal diagnosis plan is acquired.
In the medical grading, a comprehensive fuzzy evaluation method is used as a basic method, the case treatment time, the past medical history and the exercise diet condition are used as input parameters, the diagnosis and treatment characteristics of doctors are combined, the decision process is simulated, a medical grading diagnosis and treatment rule model is formed, and the medical grading is carried out on the illness state of the patient. The first-level treatment scheme and the second-level treatment scheme automatically generate two to three medical schemes for the system model, the first-level treatment scheme provides a treatment scheme through a similarity decision model through rule setting, the second-level treatment scheme provides a specific medicine dose adjustment suggestion through a fuzzy neural network model, and the third-level treatment scheme shows that the medicine dose adjustment cannot meet treatment requirements, needs actual doctors to participate, provides a new treatment scheme, and feeds back the new treatment scheme to a treatment scheme library. The information processing module collects the disease diagnosis results and treatment schemes of the three classes, combines the priori knowledge, evaluates the safety risk class and the effect class, and selects an optimal treatment scheme from the treatment schemes to feed back to the patient terminal.
In the invention, based on the prediction of a treatment scheme of a large number of calculation experiments, a large number of clinical medical data of chronic diseases are input into a machine self-learning module, a fusion layer based on specific task drive is introduced, and a knowledge graph integrated with expert doctor experience is used as prior knowledge of network training, so that a novel structure of 'expert experience + machine learning' is realized, and the advantages of an expert system and machine learning are fully exerted. The optimal solution space can be searched through a large-scale fuzzy reasoning calculation experiment, and the decision basis of the optimal treatment scheme can be explained while the optimal treatment scheme is provided.
With further reference to fig. 2 and table 1, fig. 2 is a schematic diagram of a framework for an embodiment of the diagnostic grading of the present invention, and the treatment protocol specifically includes the following grading: grading factor set U ═ diet exercise (U)1) Duration of treatment (U)2) History of previous disease (U)3) A comment set V ═ i (V1), ii (V2) and iii (V3); wherein, U1= alcohol consumption (u)11) Heart rate deviation (u)12) Allergic food (u)13)},U2Within 3 days (u)21) Within one week (u)22) Over one week (u)23)},U3Abnormal liver function (u)31) Heart disease (u)32) Abnormal renal function (u)33) }; performing first-level fuzzy evaluation on U, and setting UiIs AiK of (a)iThe comprehensive evaluation matrix of the factor to V is RiSelecting a primary model pair UiPerforming fuzzy comprehensive evaluation, and setting UiHas a fuzzy value set of Bi,Bi=Ai*Ri=(bi1,bi2,bi2) (ii) a Performing secondary fuzzy comprehensive evaluation on U, setting the factor importance degree fuzzy subset of U as A, and performing secondary comprehensive evaluation matrix
Figure BDA0003070032170000101
The result after weighted averaging is R uijAnd evaluating the diagnosis and treatment grade according to the maximum membership principle.
In the embodiment, the model is trained according to rules set in advance by combining a rule learning model in machine learning in the grading diagnosis and treatment process; the comprehensive evaluation method converts qualitative evaluation into quantitative evaluation according to the membership theory of fuzzy mathematics, namely, fuzzy mathematics is used for making overall evaluation on objects or objects restricted by various factors.
TABLE 1
Grade Class I Class II Class III
Evaluation of the State Micro-meter In general Abnormality (S)
Reasonable score 0~49 50~80 81~100
Referring to fig. 4, which is a schematic diagram of a membership function in the present invention, a T-S type fuzzy neural network includes a front network and a back network, the front network includes a membership function layer, a rule layer and a normalization layer, the membership function layer is obtained by selecting a gaussian function, and the membership function specifically is:
Figure BDA0003070032170000102
n ═ 1, 2.. n; j ═ 1, 2.. m; the rule layer is responsible for fuzzy rule output, and fuzzy calculation is carried out on fuzzy subsets of each feature output by the membership function; the form of arithmetic product is adopted as the operation method of the fuzzy rule layer, and the output of the rule layer is recorded as:
Figure BDA0003070032170000103
j ═ 1, 2,. ·, m; normalizing the output of the normalization layer rule layer, which specifically comprises the following steps:
Figure BDA0003070032170000104
Figure BDA0003070032170000105
j is 1, 2,. said, m; the back-part neural network comprises a T-S type fuzzy logic layer and an output layer, the output of the T-S type fuzzy logic layer is combined with the linear sum of the output of the normalization layer and the input layer, and the theta of the outputjComprises the following steps:
Figure BDA0003070032170000111
1, 2,. m; j is 1, 2,. said, m; the output layer is an output layer with an activation function structure and has the range of [ -1,1 [ -1 [ ]]。
Referring further to fig. 3, there is shown a schematic flow chart of the primary treatment protocol of the present invention, which specifically includes the algorithm: storing symptom information in a database in the form of vectors, wherein each piece of information comprises a symptom number and a corresponding symptom vector; a diagnosis set obtained based on prior knowledge is marked as D, and symptom vectors corresponding to all symptom numbers with diagnosis D are removed; representing the input symptoms by vectors, and calculating the similarity of the input symptoms and every other symptom vector by using cosine similarity; sorting the symptoms according to the similarity, and taking out the first 3 symptoms to be stored in an array; and displaying the whole information with the closer first 3 similarity degrees, including the number corresponding to the input symptom, the similarity degree, the symptom, the diagnosis and the medication information.
Referring to fig. 5, fig. 5 is a schematic diagram illustrating an optimal solution obtaining process of a fuzzy neural network in a secondary treatment scheme of the present invention, in the present invention, intelligent diagnosis and treatment information includes not only which kinds of drugs are prescribed, but also information such as drug dosage, usage, drug compatibility, etc., secondary diagnosis and treatment is mainly recommended for drug dosage of a patient, a machine learning model based on clinical data is a prediction model based on the fuzzy neural network, and a model construction and optimization unit of the model includes the following neurons: 1) fuzzifying neurons: converting the determined value (medicine dose) into a fuzzy output value y which is mu (x), wherein x is input of the determined value, y is output of the fuzzy value, and mu is a membership function; 2) defuzzification of neurons: the neuron is similar to the former type but has opposite action, fuzzy values are converted into determined values and then output, and the relation expression is as follows: y ═ f (x)1,x2,...,xn) The defuzzification method comprises a maximum value method and a centroid method; 3) fuzzy logic neuron: such neurons exist in the middle layer of the neural network, and the action expression is as follows: θ is I (x, w), y is g (θ), where I (×) is a logical fuzzy function and g (×) is an output function; the fuzzy neural network has three parameters, namely the center c and the variance sigma of each membership functionSetting a Gaussian function for determining the mean value and the variance for fast approaching the optimal solution, and immediately obtaining the initial value of the linear weight on the Gaussian function according to the probability; and (4) updating weight parameters of the neural network by combining the BP algorithm.
By utilizing the universal approximation capability of the T-S type fuzzy neural network, the patient sign data is used as input, and the output is the change condition (divided into increase, constant and decrease) of the medicament dosage, wherein the increase and decrease are given with known dosage and amplitude, and the medicament dosage is increased by only one span each time.
The training of the model mainly comprises training and learning of intelligent drug dose recommendation, the intelligent drug dose recommendation model respectively establishes prediction models for different types of diseases, the prediction models are trained according to different symptom characteristics, and supervised learning is carried out by utilizing a training data set with doctor actual experience diagnosis labels to obtain a related dose increase and decrease model. The training model based on clinical data mainly utilizes a deep learning method, when the characteristics are input, firstly fuzzification and normalization processing are carried out on the characteristics of each physical sign through a front network, information is spread layer by layer, then the back network utilizes a connection weight to improve linear correlation among the characteristics, and finally defuzzification is carried out to output a result. A large amount of clinical pathology is learned, and the incidence relation between the increase and decrease dosage and the body recovery effect is found, so that the intelligent recommendation of changing the dosage of the medicine is realized, and the body recovery of a patient is facilitated.
The third-level treatment scheme is adjusted by a senior doctor; the purpose of tertiary treatment is to solve the problem that abnormal data cannot be subjected to model calculation. And if the data are abnormal, reporting the abnormal data to the hospital. When a professional doctor makes a consultation, modern remote medical technologies such as remote conferences, remote imaging, remote diagnosis and consultation, remote nursing and the like are involved. If the doctor and the patient do not directly communicate, the professional doctor gives a set of new drug treatment scheme through experience, transmits the new drug treatment scheme to the cloud intelligence library, and sends the new drug treatment scheme to the patient after the safety level is evaluated. After the patient is diagnosed, the healing process is possibly long, long-term medication is needed, the doctor cannot know the condition of the patient in real life in real time, the patient condition can be monitored for a long time through the cloud-end cooperative remote medical treatment and grading monitoring platform, reasonable treatment is executed, the conditioning scheme is periodically updated, and the patient treatment is completed by better matching with a hospital.
Preferably, the information collected by the data collection module is one or more of medical record information, assay result information, daily monitoring result information and imaging report information, necessary data is periodically obtained, privacy of user data is protected, different terminals log in at a single point (such as a hospital) and upload the patient data to the cloud, the transmission part passes through a 5G mobile network, the frequency of the 5G mobile network is high, the data is accurate, the algorithm is accurate, and the data information is uploaded in time; HTTPS is used in the middle, and the SSL protocol ensures the security of data.
Preferably, the information processing module further comprises an information updating module configured to perform integration and update of the same patient case information based on the input case information and pre-stored case information.
Preferably, the interactive terminal module comprises a mobile terminal, and the mobile terminal is a mobile phone, a computer, a tablet or a bracelet.
Preferably, intelligence wearing equipment data acquisition module includes bracelet etc. and bracelet embeds contact sensor, but real-time supervision human body temperature data, and the bracelet measures the body temperature result and follows mercury clinical thermometer error deviation 0.1 degree from top to bottom, can realize real-time body temperature monitoring's high frequency record through the bracelet, still has and looks over the amount of exercise, monitors the sleep quality, and functions such as intelligent alarm clock awakens up. The exercise amount can be checked in real time through mobile phone application, walking and running effects are monitored, and data are transmitted to the cloud end through a mobile phone or a computer. The multifunctional clothes rack has the functions of convenience in wearing or convenience and practicability, real-time monitoring, important reminding and the like. The intelligent detection equipment data acquisition module comprises equipment such as a blood pressure meter, a blood glucose meter or a uric acid meter, and the patient uploads acquired information to the cloud end for intelligent monitoring so as to determine the treatment effect.
It should be noted that in the description of the present invention, the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicating the directions or positional relationships are based on the directions or positional relationships shown in the drawings, which are only for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.
The terms "comprises," "comprising," or any other similar term are intended to cover a non-exclusive inclusion, such that a process, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, article, or apparatus.
So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.

Claims (8)

1. A telemedicine and grading monitoring system based on cloud-terminal cooperation is characterized by comprising a data acquisition module, an interaction terminal module and a cloud data integration module, wherein the data acquisition module and the interaction terminal module are in communication connection with the cloud data integration module;
the data acquisition module is used for acquiring medical data of a patient; the data acquisition module comprises an intelligent wearable device data acquisition module and an intelligent detection device data acquisition module, and is respectively used for data acquisition of the patient long-term wearable device and the patient temporary detection device;
the interactive terminal module is used for single sign-on of a patient, data input and diagnosis information output;
the cloud data integration module comprises a data receiving module, an information processing module and an information output module, and the data receiving module and the information output module are in communication connection with the information processing module; the data receiving module is used for receiving the data output by the data acquisition module; the information processing module comprises a database and a machine self-learning module, and the database is used for storing various case information and case auxiliary strategies; the machine self-learning module processes based on actual case information and stored case information, automatically generates a treatment scheme, compares the automatically generated treatment scheme with an expert data customization scheme input from the outside and outputs a final disease treatment scheme; the information output module transmits the final disease treatment scheme to the interactive terminal module based on the received final disease treatment scheme; the treatment regimen comprises a first treatment regimen, a second treatment regimen, and a third treatment regimen; the first treatment scheme is a first-level treatment scheme, and specifically comprises the steps of abstracting received case data into symptoms, searching similar cases based on the symptom characteristics and cosine similarity stored in the database, obtaining similar cases, and formulating a diet work and rest suggestion scheme based on the similar cases; wherein symptoms are stored in vector form; the second treatment scheme is a secondary treatment scheme, and specifically comprises the steps of outputting a change scheme of the medicament quantity based on the received case information by utilizing a universal approximation theorem of a T-S type fuzzy neural network, wherein the change scheme comprises increasing a preset dose, keeping the dose unchanged and reducing the preset dose; the third treatment plan is a three-level treatment plan, and specifically comprises a final treatment plan which is established by carrying out multi-party remote consultation based on abnormal case data information;
the grade of the treatment scheme is divided into fuzzy grades, and the fuzzy grade specifically comprises the following steps: dividing the factor set into N factor subsets according to the dividing factor set U and the comment set V; performing primary fuzzy comprehensive judgment on U, and setting the fuzzy subset of the importance degree of U as A and UiK ofiThe comprehensive evaluation matrix of the factor to V is RiAnd the comprehensive evaluation set is Bi=Ai*Ri(ii) a Performing two-stage fuzzy comprehensive evaluation on U, and setting the factor importance degree fuzzy subset of U as A and the two-stage comprehensive evaluation matrix as
Figure DEST_PATH_IMAGE001
And (5) carrying out diagnosis and treatment grade evaluation according to the maximum membership principle.
2. The cloud-terminal collaboration based telemedicine and hierarchical monitoring system as claimed in claim 1, wherein the T-S type fuzzy neural network comprises a front piece network and a back piece network, the front piece network comprises a membership function layer, a rule layer and a normalization layer, the membership function layer is obtained by selecting a gaussian function, and the membership function is specifically:
Figure 323284DEST_PATH_IMAGE002
(ii) a The rule layer is responsible for fuzzy rule output, and fuzzy calculation is carried out on fuzzy subsets of each feature output by the membership function; adopting the form of arithmetic product as the operation method of the fuzzy rule layer, and recording the output of the rule layer as:
Figure DEST_PATH_IMAGE003
(ii) a The normalization layer rule layer outputs are normalized, and specifically:
Figure 37162DEST_PATH_IMAGE004
the back-up network comprises a T-S type fuzzy logic layer and an output layer, and the T-S type fuzzy logic layerOutput of edit layer combined with linear sum of output and input layers of normalization layerθ j Comprises the following steps:
Figure DEST_PATH_IMAGE005
(ii) a The output layer is an output layer with an activation function structure and has the range of [ -1,1 [ -1 [ ]]。
3. The cloud-terminal collaboration based telemedicine and grading monitoring system as claimed in claim 1, wherein the primary treatment scheme specifically comprises an algorithm of: storing symptom information in a database in the form of vectors, wherein each piece of information comprises a symptom number and a corresponding symptom vector;
a diagnosis set obtained based on prior knowledge is marked as D, and symptom vectors corresponding to all symptom numbers with diagnosis D are removed;
representing the input symptoms by vectors, and calculating the similarity of the input symptoms and every other symptom vector by using cosine similarity;
sorting the symptoms according to the similarity, and taking out the memory with the highest similarity in the array;
and displaying the whole piece of information with the highest similarity, including the number corresponding to the input symptom, the similarity, the symptom, the diagnosis and the medication information.
4. The cloud-terminal collaboration based telemedicine and hierarchical monitoring system as claimed in claim 1, wherein the information collected by the data collection module is one or more of medical record information, assay result information, daily monitoring result information and imaging report information.
5. The cloud-terminal collaboration based telemedicine and hierarchical monitoring system as claimed in claim 1, wherein the information processing module further comprises an information updating module configured to perform integration and updating of the same patient case information based on the input case information and pre-stored case information.
6. The cloud-terminal collaboration based telemedicine and hierarchical monitoring system as claimed in claim 1, wherein the interactive terminal module comprises a mobile terminal, the mobile terminal being a mobile phone, a computer, a tablet or a bracelet.
7. The cloud-terminal collaboration based telemedicine and hierarchical monitoring system as claimed in claim 1, wherein the smart wearable device data collection module comprises a bracelet;
the intelligent detection equipment data acquisition module comprises a blood pressure meter, a blood glucose meter or a uric acid meter.
8. The cloud-terminal collaboration based telemedicine and hierarchical monitoring system as claimed in any one of claims 1 to 7, wherein the communication in the system employs a 5G network.
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